JPS63283870A - Endless cutter - Google Patents

Abstract

PURPOSE:To provide a sufficient mechanical strength for cutting and groove working by permitting the fine working with high precision and fine groove working by installing a reinforcing basic body for a metal layer at least on one side surface of the abrasive grain cutting edge layer in hollow band form which is formed through electroplating. CONSTITUTION:A reinforcing basic body 8 which has an abrasive grain cutting edge layer 7 in hollow band form which is prepared through electroplating and consists of a metal layer for reinforcing the abrasive grain cutting edge layer 7 at least on one side surface is installed. Since the abrasive grain cutting edge layer 7 in hollow band form is formed through electroplating, a seamless structure can be obtained, and also uneveness and step difference do not exist on the side surface of the abrasive grain cutting edge layer 7, and an exceedingly flat surface can be obtained. Therefore, the fine working with high precision can be carried out. Further, since the thickness of the cutting edge can be maed very thin, fine groove work can be carried out. Further, due to the reinforcement by the reinforcing basic body 8, the sufficient mechanical strength necessary for cutting and groove working can be provided.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an electroformed endless cutter that cuts or grooves a workpiece by traveling around between boars.

[Conventional technology]

Wafer cutting processing or ceramic, ferrite,
Endless cutters such as Pantone and belt saws are widely used for grooving and cutting glass, precious metals, etc. This type of endless cutter is shown in Figure 6.
A hollow band 1 is formed by joining both ends of a band-shaped plate made of iron by welding or the like, and a grindstone having a U-shaped cross section as shown in FIG. It consists of a grain cutting edge 2 formed thereon.

Generally, this type of endless cutter 3 is hooked around a drive pulley 4 and a driven pulley 5, receives driving force from the drive pulley 4, and travels around between the pulleys 4.5. By pressing the workpiece 6 against the abrasive cutting edge 2 during this circular travel, the desired cutting or grooving of the core workpiece 6 is achieved.

[Problem that the invention seeks to solve]

However, in the above-mentioned conventional endless cutter, since both ends of the band 1 are joined together by welding or the like, there is a problem in that unevenness and steps are generated at the joint 9, which adversely affects processing accuracy. Also,
Since the mechanical strength of the seam 9 is lower than that of other smooth parts, there is a disadvantage that the band breaks from the seam 9.

Furthermore, since the abrasive cutting edge 2 is fitted into the band l of the metal plate, the thickness of the band 1 itself cannot be made extremely thin, and as a result of the abrasive cutting edge 2 being fitted therein,
There is an inconvenience that the abrasive cutting edge 2 has a considerably thick blade, making it impossible to cut fine grooves. Furthermore, when machining an expensive workpiece 6 such as a precious metal, a large cutting allowance is inevitably required, which causes a problem of large economic losses.

The present invention was made to solve the above-mentioned conventional problems, and its purpose is to eliminate the deterioration of processing accuracy and strength reduction caused by band joints, and to reduce the thickness of the abrasive cutting edge. To provide an endless cutter capable of machining extremely fine grooves without any trouble.

[Means for solving problems]

In order to achieve the above object, the present invention is configured as follows. That is, the endless cutter according to the present invention has a hollow band-shaped abrasive cutting edge layer produced by electroforming, and a nuclear abrasive cutting edge layer is provided on at least one side surface of this abrasive cutting edge layer. The structure is characterized by being provided with a reinforcing base made of a reinforcing metal layer.

(Function) In the present invention configured as described above, since the hollow band-shaped abrasive cutting edge layer is produced by electroforming, there is no seam at all, and the side surface of the abrasive cutting edge layer has no seams. It is extremely flat with no unevenness or steps.

Therefore, precision machining with high accuracy is possible, and the blade thickness can be made extremely thin, making it possible to machining extremely fine grooves. Furthermore, since the abrasive cutting edge layer is reinforced by the reinforcing base, it has sufficient mechanical strength required for cutting and grooving.

〔Example〕

Embodiments of the present invention will be described below based on the drawings.

1-3 illustrate embodiments of various aspects of the invention. In the figure, abrasive cutting edge layers 7.7a and 7b are hollow band bodies seamlessly formed by electroforming.
The abrasive grains are grown by precipitation together with Ni. Also,
The reinforcing bases 8.8a and 8b in FIGS. 1 and 2 are plated with Ni, which is precipitated and grown on one side or both sides of the nuclear abrasive cutting edge layer 7, leaving the cutting edge 10 of the abrasive cutting edge layer 7. This layer reinforces the mechanical strength of the abrasive cutting edge N7. The reinforcing base 8 shown in FIG. 3 also has two abrasive cutting edge layers 7a,
The abrasive cutting edge layers 7a and 7b are sandwiched from both sides by the abrasive cutting edge layers 7a and 7b. As mentioned above, in each embodiment of FIGS. 1 to 3, each abrasive cutting edge layer 7.7a, 7b and reinforcing base 8.8a, 8
b constitutes an endless cutter, and this endless cutter is manufactured as follows.
.

First, the production of the endless cutter shown in Fig.
As shown in the figure, first, a cylindrical ring-shaped master mold 11 is coated with an insulating material 12 except for the inner circumferential surface, and the coated master mold 11 is coated with an electric current containing, for example, nickel sulfate and abrasive grains. It is immersed in a casting bath liquid and subjected to electroforming treatment by well-known means. Through this electroforming process, a mixture of Ni and abrasive grains is electrodeposited on the inner circumferential surface of the master die 11, and a hollow band-shaped abrasive cutting edge layer 7 is formed.

Next, the mother mold 11 is taken out from the electroforming bath liquid, the cutting edge portion of the abrasive cutting edge layer 7 is coated with an insulator 13, and the coated mother mold 11 is then electroformed with Ni electroforming that does not contain abrasive grains. Electroforming is performed by immersing it in a bath solution. Through this electroforming process, a Ni reinforcing base 8 is electrodeposited on one side surface of the abrasive cutting edge layer 7, leaving the cutting edge portion. After this electroforming process, if the insulator 13 is removed and the electrodeposition product consisting of the abrasive grain broken solid layer 7 and the reinforcing base 8 is peeled off from the matrix 11, the endless cutter shown in FIG. 1 can be obtained. Become.

The endless cutter shown in FIG. 2 is formed by electrodeposition as follows. That is, for example, after forming the endless cutter shown in FIG. 1 as described above, the non-electrodeposited parts (the reinforcing base 8a and the cutting edge 10) are covered with an insulator, and then the cutter is formed in a Ni electroforming bath containing no abrasive particles. By carrying out the required electroforming treatment, the desired Ni reinforcing base 8b is electrodeposited on the peripheral surface of the abrasive grain cut solid layer 7, and the endless cutter shown in FIG. 2 is obtained.

In addition, the endless cutter shown in FIG. 3 first forms an abrasive cut solid layer 7a by electrodeposition on the inner peripheral surface of the matrix 11 in a Ni electroforming bath liquid containing abrasive grains, and then A reinforcing base 8 made of Ni plating is formed by electrodeposition on the surface of the abrasive grain cut solid layer 7a in a Ni electroforming solution containing no grains, and finally, the abrasive grains are deposited again in a Ni electroforming bath solution containing abrasive grains. It is obtained by forming a cut solid layer 7b on the surface of the reinforcing base 8 and peeling off the electroformed product consisting of these 3i7a and 8.7b from the matrix 11.

As mentioned above, the endless cutter of this embodiment has the abrasive grain cutting solid layer 7.7a, 7b and the reinforcing base 8.8a, 8.
b by electrodeposition by electroforming. By forming the endless cutter by electroforming in this way, there is no band seam that occurs in the conventional example, so the surface of the endless cutter (abrasive grain cut solid layer) has no unevenness or step and is extremely flat. A side surface of the cutting edge is obtained, thereby making it possible to achieve precision machining with high precision. Further, since the endless cutter of this embodiment has no seams and is reinforced by the reinforcing bases 8.8a and 8b, it has sufficient mechanical strength.

Furthermore, since the abrasive grain cutting solid layers 7.7a and 7b are formed by electroforming, the blade thickness of the cutting edge 10 is extremely thin (<2 in this example).
By using the endless cutter shown in Figures 1 and 2, it is possible to form extremely fine grooves (thickness of 0μ to 30μ). When processing, economic losses can also be reduced. The endless cutter shown in FIG. 3 is used for cutting or for cutting grooves wider than the cutters shown in FIGS. 1 and 2.

In addition, in the above embodiment, the abrasive grain broken solid layers 7.7a, 7b,
Although the reinforcing bases 8.8a and 8b are formed by electroforming using Ni as a base, the present invention is not limited thereto, and may be formed using other metals such as copper, chromium, or other desired metals as a base. It may also be formed by electroforming.

In addition, in this embodiment, the abrasive grain broken solid layers 7.7a, 7b,
Although the reinforcing base bodies 8.8a, 8b are both formed by electroforming, it is also possible to form the reinforcing base bodies 8.8a, 8b by other means, such as vapor deposition or sputtering.

Further, in the above embodiment, the cutting edge lO is formed protruding from one end edge of the endless cutter, but it may be formed protruding from both end edges of the endless cutter.

〔Effect of the invention〕

Since the present invention is configured as explained above,
There are no seams in the abrasive cutting solid layer, and the sides of the cutting edge are also electroformed, making them extremely flat.
This allows for highly accurate precision machining.

In addition, since the abrasive grain cutting solid layer can be formed thinly, ultra-fine thin processing is possible, and since the abrasive grain cutting solid layer is seamless and reinforced with a reinforcing base, it is easy to cut and groove. It becomes possible to have both the necessary and sufficient mechanical strength.

[Brief explanation of the drawing]

1 to 3 are cross-sectional views showing examples of various aspects of the endless cutter according to the present invention, FIG. 4 is an explanatory view showing an example of electroforming manufacturing of the endless elater according to the present invention, and FIG. FIG. 6 is a sectional view showing a conventional endless cutter, and FIG. 6 is an explanatory view showing how the endless cutter is used. L... Band, 2... Abrasive cutting edge, 3... Endless cutter, 4... Drive pulley, 5... Driven pulley, 6... Workpiece, 7.7a, 7b. ... Abrasive grain cutting solid layer, 8.8a, 8b... Reinforced base, 9... Seam, 10... Cutting edge, 11... Matrix, 12.13 ・
··Insulator. Applicant DISCO Co., Ltd. Agent Patent Attorney Arashi Izo Erased Figure 1 Figure 2 Figure 3 Figure 4 Figure 31U

Claims (4)

[Claims] (1) It has a hollow band-shaped abrasive cutting edge layer produced by electroforming, and at least one side surface of this abrasive cutting edge layer is made of a metal layer that reinforces the core abrasive cutting edge layer. An endless cutter characterized by being provided with a reinforced base. (2) The endless cutter according to claim 1, wherein the reinforcing base is constituted by a metal plating layer. (3) The reinforcing base is formed narrower in width than the abrasive grain cutting edge layer, and covers the side surface of the core abrasive grain cutting edge layer while leaving the cutting edge portion of the abrasive grain cutting edge layer. An endless cutter according to claim 1 or 2. (4) The reinforcing base is sandwiched between abrasive grain cutting edge layers on both sides, and the core reinforcement base reinforces the abrasive grain cutting edge layers on both sides. An endless cutter according to claim 1 or 2.